KR102431593B1 - Apparatus for inspecting using x-ray transmission and method thereof - Google Patents

Abstract

An object of the present invention is to provide an X-ray transmission inspection apparatus and an X-ray transmission inspection method capable of preventing over-detection or erroneous detection of foreign substances even when there is a change in position in the height direction of the sample.
An X-ray source 2 for irradiating X-rays X to the sample S, a sample moving mechanism 3 for continuously moving the sample in a specific direction while irradiating X-rays from the X-ray source, and a side opposite to the X-ray source with respect to the sample A TDI sensor (4) installed in the to detect X-rays passing through the sample, a distance sensor (5) for measuring the distance between the X-ray source and the sample, and a TDI in real time based on the change in the distance measured by the distance sensor A TDI control unit 6 for controlling the TDI sensor by changing the charge transfer speed of the sensor 4 is provided.

Description

X-ray transmission inspection apparatus and X-ray transmission inspection method

The present invention relates to an X-ray transmission inspection apparatus and an X-ray transmission inspection method capable of detecting a minute foreign material or the like in a sample, and particularly capable of detecting a foreign material having a size of several tens of μm or less.

In general, in order to detect a foreign material such as a minute metal in a sample, an X-ray transmission inspection in which an X-ray transmission image is obtained by irradiating a sample with X-rays is used. For example, in recent years, in lithium ion secondary batteries employed in automobiles, hybrid vehicles, electric vehicles, etc., an electrode serving as a positive electrode has a lithium Mn oxide film or a lithium Co oxide film formed on both surfaces of an Al film. Therefore, when foreign substances of several tens of µm or more, such as Fe or SUS, are mixed, there is a fear that a short circuit may occur, resulting in loss of battery or deterioration in performance.

As an X-ray transmission inspection apparatus for detecting foreign substances in such a sample, it is known that, when performing an in-line inspection, an X-ray source and an X-ray detector such as a line sensor are arranged opposite to each other so as to sandwich a moving sample in one direction. have. For example, Patent Document 1 proposes an X-ray foreign material inspection apparatus that detects even a minute foreign material with high sensitivity by using a TDI sensor.

This X-ray foreign material inspection apparatus includes an X-ray image intensifier (image intensity amplifying device: IIF), a TDI sensor, and an X-ray transmission image moving on the imaging plane of the X-ray image intensifier; Synchronization of the charge transport speed of the TDI sensor, and the distance b, from the X-ray source to the foreign object (actually a belt conveyor), the image formed on the input screen of the X-ray image intensifier with respect to the moving speed V of the belt conveyor; By the distance a from the X-ray source to the input screen of the X-ray image intensifier, it is enlarged at the optical magnification b/a, and the moving speed of the image of the foreign object formed on the TDI sensor depends on the moving speed V of the belt conveyor. It is described that it becomes the velocity V ₃ multiplied by b/a and others.

That is, in this X-ray foreign material inspection apparatus, synchronizing the movement speed of the sample and the charge movement speed of the TDI sensor, and the preset distance (FOD) from the X-ray source to the foreign material (actually, the mounting surface of the belt conveyor) and the optical magnification ratio by the ratio (FDD/FOD) of the distance (FDD) from the X-ray source to the X-ray detector is used as a correction factor.

Japanese Patent Laid-Open No. 2004-257884

The following problems remain with the said prior art.

That is, in the conventional X-ray transmission inspection apparatus, even if it is the charge transfer rate of the TDI sensor with the optical magnification factor added, the inspection is performed by keeping it constant. In the detection surface, the focal position of the X-ray transmission image is changed, and even if the same foreign material is detected in the same sample, there is a problem in that the degree of integration of the detection signal by the TDI sensor is different and the image is blurred. As described above, when there is a position change in the height direction of the sample, there is a fear that over-detection or erroneous detection of foreign substances in the sample occurs.

The present invention has been made in view of the above problems, and an object of the present invention is to provide an X-ray transmission inspection apparatus and an X-ray transmission inspection method capable of preventing over-detection or erroneous detection of foreign substances even when there is a position change in the height direction of the sample. do it with

In order to solve the said subject, this invention employ|adopted the following structures. That is, the X-ray transmission inspection apparatus of the present invention comprises: an X-ray source for irradiating X-rays to a sample; a sample moving mechanism for continuously moving the sample in a specific direction while irradiating X-rays from the X-ray source; A TDI sensor that is installed on the opposite side of the X-ray source to the sample and detects the X-ray that has passed through the sample, a distance sensor that measures the distance between the X-ray source and the sample, and the distance measured by the distance sensor It is characterized in that the TDI controller is provided for controlling the TDI sensor by changing the charge transfer speed of the TDI sensor in real time based on the fluctuation.

In this X-ray transmission inspection apparatus, since the TDI sensor is controlled by changing the charge transport speed of the TDI sensor in real time based on the change in the distance measured by the distance sensor, the change in the distance is sensed in real time, and the change By reflecting each time on the charge transport speed, it is possible to optimize the focal position of the X-ray transmission image and prevent blurring of the image. In addition, since it does not involve a physical operation, the charge transfer speed of the TDI sensor can be changed instantaneously in real time, and since the time required for a series of control corresponding to the fluctuation is short, the data acquisition interval can be shortened. This makes it possible to acquire more precise data, and enables high-accuracy position correction of the sample.

An X-ray transmission inspection apparatus according to a second invention is a laser distance sensor in the first invention, wherein the sample has a band shape, and the distance sensor measures the distance by reflection of a laser beam emitted toward the sample, It is characterized in that the laser beam is irradiated in the form of a linear spot extending in a direction crossing the moving direction of the sample and in the width direction of the sample.

That is, in this X-ray transmission inspection apparatus, since the distance sensor irradiates the laser beam in the form of a linear spot extending in the direction intersecting the movement direction of the sample and in the width direction of the sample, measurement in two dimensions is achieved, It is possible to grasp the positional variation of the region, and further improvement of the precision can be achieved.

An X-ray transmission inspection method according to a third aspect of the present invention comprises an X-ray irradiation step of irradiating X-rays to a sample with an X-ray source, and continuously moving the sample in a specific direction while irradiating X-rays from the X-ray source. A sample moving step, an X-ray detection step of detecting the X-ray that has passed through the sample with a TDI sensor installed on the opposite side to the X-ray source with respect to the sample, and measuring the distance between the X-ray source and the sample with a distance sensor It characterized in that it has a distance measurement step and a TDI control step of controlling the TDI sensor by changing the charge transfer speed of the TDI sensor in real time based on a change in the distance measured by the distance sensor.

The X-ray transmission inspection method according to the fourth invention is a laser distance sensor in the third invention, wherein the sample has a band shape, and the distance sensor measures the distance by reflection of a laser beam emitted toward the sample, It is characterized in that the laser beam is irradiated in the form of a linear spot extending in a direction crossing the moving direction of the sample and in the width direction of the sample.

ADVANTAGE OF THE INVENTION According to this invention, the following effect is shown.

That is, according to the X-ray transmission inspection apparatus and the X-ray transmission inspection method according to the present invention, the TDI sensor is controlled by changing the charge transfer speed of the TDI sensor in real time based on the change in the distance measured by the distance sensor, Blurry of the line transmission image can be prevented. Therefore, even if there is a position change in the height direction of the sample, overdetection or erroneous detection of foreign matter can be prevented.

1 is a schematic overall configuration diagram showing a first embodiment of an X-ray transmission inspection apparatus and an X-ray transmission inspection method according to the present invention.
2 is a perspective view showing a TDI sensor according to the first embodiment.
It is explanatory drawing which shows the distance measurement method by a distance sensor in 1st Embodiment.
Fig. 4 is an explanatory diagram showing a distance measurement method using a distance sensor in a second embodiment of the X-ray transmission inspection apparatus and the X-ray transmission inspection method according to the present invention.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment of the X-ray transmission inspection apparatus and X-ray transmission inspection method which concern on this invention is demonstrated, referring FIGS.

The X-ray transmission inspection apparatus of this embodiment, as shown in FIG. 1, is the X-ray source 2 which irradiates X-ray X with respect to the sample S, and the sample S while irradiating the X-ray X from the X-ray source 2 a sample moving mechanism 3 for continuously moving the sample S in a specific direction; 2) and the distance sensor 5 that measures the distance between the sample S, and the charge transfer speed of the TDI sensor 4 in real time based on the change in the distance measured by the distance sensor 5 when the sample S moves A TDI control unit 6 for controlling the TDI sensor 4 is provided.

Further, the X-ray transmission inspection apparatus 1 of the present embodiment includes a main control unit 7 connected to and controlling each of the above-described components, and a display unit displaying a transmitted image showing the distribution of the detected transmitted X-ray intensity 8) is provided.

The main control unit 7 is a computer constituted by a CPU or the like. It includes an arithmetic processing circuit and the like for generating a transmitted image by performing image processing based on a signal from the input TDI sensor 4 and displaying the image on the display unit 8 .

The display unit 8 is a display device connected to the main control unit 7 to display a contrast image and the like. The display unit 8 can display various information according to the control from the main control unit 7 .

The X-ray source 2 is an X-ray tube capable of irradiating X-ray X, and the hot electrons generated from the filament (cathode) in the tube are accelerated by the voltage applied between the filament (cathode) and the target (anode), so that the W of the target X-rays X generated by colliding with (tungsten), Mo (molybdenum), Cr (chromium), etc. are emitted from a window such as beryllium foil as primary X-rays.

The sample S is, for example, a material for a Li-ion battery formed in a strip shape or a material used in the pharmaceutical industry.

The sample S is, for example, a material for a Li-ion battery formed in a strip shape or a material used in the pharmaceutical industry. For example, when the sample S is an electrode sheet or the like used for a Li-ion secondary battery, the foreign matter mixed therein is, for example, Fe or SUS, which is likely to be mixed into the electrode as a foreign material.

The sample moving mechanism 3 is, for example, a motor or the like that is relatively movable in the extension direction of the sample S with respect to the TDI sensor 4 . The sample moving mechanism 3 includes, for example, at least a pair of rollers (approximately shown) for moving the strip-shaped sample S in the extending direction in a roll-to-roll manner.

Moreover, in order to quantify the movement amount of the sample S, the linear scale 9 is provided in the sample movement mechanism 3, and the movement amount of the sample S can be measured with the measurement pitch Ls.

As shown in FIG. 2, the TDI (Time Delay Integration) sensor 4 is an X-ray detector in which a plurality of cells (sensor elements) are arranged in directions perpendicular to and parallel to the moving direction of the sample S. A phosphor 4b disposed on the detection surface 4a, a FOP (fiber optics plate) 4c in which a plurality of optical fibers are two-dimensionally arranged vertically and horizontally under the phosphor 4b, and an FOP ( 4c) The Si light-receiving element 4d disposed below is provided, and it has a structure as if a plurality of line sensors were arranged in a row. For example, 200-1000 steps of unit line sensors are lined up in the transfer direction of the sample S, and the TDI sensor 4 is comprised.

In the TDI sensor 4, a phosphor 4b such as CsI (cesium iodide), GOS (gadrinium oxysulfide), or YAG (yttrium aluminum garnet) is used.

In the TDI sensor 4, charge accumulation and charge transfer are performed at the sensor pitch Lt. The line rate is usually about 0.5 to 100 kHz.

The said distance sensor 5 is a reflection type laser distance sensor which measures the said distance by reflection of the laser beam L emitted toward the sample S. This distance sensor 5 is disposed opposite to the sample S from the X-ray source 2 side, and irradiates the sample S with a laser beam L in the form of a dotted spot. Based on the reflected light, the sample is mainly trigonometry Measure the distance between S and the X-ray source (2). In addition, the distance measurement result of the distance sensor 5 is sent to the TDI control part 6 .

This distance sensor 5 has a repeatable measurement accuracy of about 0.01 µm, a response frequency of 300 kHz or more, and a sampling time of several tens of µs, enabling high-precision real-time measurement in a very short time.

Although the spot shape of the distance sensor 5 is point-like, by taking the point of the laser beam L on the moving sample S, as shown in FIG. 3, it becomes measurement in one dimension (line shape). At this time, the measurement interval of the distance FOD' from the X-ray source 2 to the sample S is determined from the response speed of the distance sensor 5 to be used and the response speed of the charge transfer speed of the TDI sensor 4 .

In addition, the distance sensor 5 may be a distance sensor using the other principle which can achieve the same objective.

The TDI control unit 6 adjusts the direction and speed of charge transfer of the TDI sensor 4 to the moving direction and speed of the sample S, and the TDI sensor 4 in the detection area of the light-receiving surface 4a It has a function of integrating the luminance values of the received X-rays X.

That is, the TDI control unit 6 controls when there is no fluctuation in the height direction of the sample S, and the rate of charge transfer (charge transfer rate) in the detection region of the TDI sensor 4 with respect to the speed V _s of the sample S. ) V _TDI and the driving direction are set to be the same, and the flow of the sample S and the integration process of the TDI sensor 4 are synchronized and controlled.

In addition, arrow Y1 in the figure is the moving direction of the sample S, and arrow Y2 is the TDI driving direction of the TDI sensor 4 .

Further, the TDI control unit 6 determines the magnification ratio of the TDI sensor 4 (the magnification ratio when the image on the sample S is projected on the light-receiving surface 4a), and at this magnification, the TDI sensor 4 has the ability to control

That is, the TDI control unit 6 corrects the divider 6a that calculates the magnification N of the TDI sensor 4 and the magnification N obtained by the divider 6a and sets it as the corrected magnification N', and the correction magnification N ', a correction unit 6b for calculating the charge transfer rate at a rate obtained by correcting the moving speed of the sample S is provided.

The divider 6a is an enlargement ratio of the TDI sensor 4 based on the ratio "Lt/Ls" between the measurement pitch Ls of the linear scale 9 for measuring the movement amount of the sample S and the TDI pitch Lt of the TDI sensor 4 It has a function of calculating N as a fixed value and sending it to the correction unit 6b.

The magnification N is a fixed value, and is calculated by the formula "N=(Lt/Ls) x (FOD/FDD)". In this case, FOD is a fixed value, and is the distance between the X-ray source 2 and the sample S in a non-variable state.

The divider 6a is, for example, a device having a circuit that adds a signal of a frequency f1 and obtains an output of a frequency f2 (f2 = f1/n, n: integer) synchronized thereto, and is It uses a counting circuit to drop the frequency down to integers.

The correction unit 6b includes the distance FOD' from the X-ray source 2 to the sample S measured in real time by the distance sensor 5, and the distance between the X-ray source 2 and the light-receiving surface 4a as a fixed value. Using the FDD ratio "FOD'/FDD" as a factor, the magnification N sent from the divider 6a is corrected and the corrected magnification N' is used, and the charge transfer rate of the TDI sensor 4 based on the corrected magnification N'. It has a function to determine and send to the TDI sensor (4).

The correction magnification N' is calculated in real time by the formula "N' = (Lt/Ls) x (FOD'/FDD)" with the change of the distance FOD' measured at all times. Here, "real time" is determined by the line rate of the TDI sensor 4 and the sampling time of the distance sensor 5 to be used, and by shortening the sampling time of the distance sensor 5 as much as possible, more precise control becomes possible

Next, the X-ray transmission inspection method using the X-ray transmission inspection apparatus of this embodiment is demonstrated. In this X-ray transmission inspection method, for example, a positive electrode sheet in a Li ion secondary battery is used as a sample S to be inspected, and the object thereof is to detect a foreign material therein.

First, the sample S is moved between the opposing X-ray source 2 and the TDI sensor 4 at a constant speed by the sample moving mechanism 3 . In addition, this sample S has a very small thickness compared to the distance between the sample S and the TDI sensor 4 .

In this state, the distance FOD' between the X-ray source 2 and the sample S is calculated from the measurement result of the distance sensor 5 .

Next, while irradiating X-rays X from the X-ray source 2 to the sample S, the TDI sensor 4 detects the transmitted X-rays passing through the sample S and foreign substances. In addition, since the sample S is moved in a fixed direction by the sample moving mechanism 3, the entire sample S is scanned in the moving direction, and the overall intensity distribution with respect to the transmitted X-rays is obtained.

In addition, the transmitted X-ray intensity distribution obtained as described above is image-processed by the main control unit 7 to create a transmitted image, and the transmitted image is displayed on the display unit 8 . In addition, at this time, since the amount of X-ray transmission is different in the portion where the foreign material is present compared to the portion in which the foreign material is not present, the contrast of the portion in which the foreign material is present is different from that of others, so that the foreign material is present and It is possible to detect what exists.

When the sample S is moved, for example, when the sample S moves upward due to the condition of the sample moving mechanism 3 and causes a position change in the height direction, the distance FOD' between the X-ray source 2 and the sample S is getting bigger At that time, in the case of a conventional device that does not have a mechanism corresponding to this fluctuation, the contrast and intensity distribution by the foreign material are different due to the size of the X-ray generation point, and the intensity of the contrast by the foreign material is difficult to understand. , the detection of foreign substances may become difficult.

However, in this embodiment, the divider ( Using the enlargement ratio N calculated by 6a), the correction unit 6b corrects the enlargement ratio N and calculates the corrected enlargement ratio N'. Based on this correction enlargement ratio N', the TDI control unit 6 determines a new charge transfer speed of the TDI sensor 4 to control the TDI sensor 4 .

That is, if the charge transfer rate before the fluctuation is v, the new charge transfer rate v' after the fluctuation is calculated by the formula "v'=vx(FOD'/FDD)". Accordingly, the TDI control unit 6 controls the TDI sensor 4 at the charge transfer rate v'.

Thereby, when a change in the focus position of the image input to the TDI sensor 4 occurs due to a change in the height position of the sample S, the optimal focus position can be reproduced by appropriately changing the charge transfer rate.

Therefore, since the distance sensor 5 always measures the distance FOD' and corrects the charge transfer speed of the TDI sensor 4 based on the corrected magnification N' corrected in response to the change, the sample S moves upward or downward. Even if it moves to and causes a positional change in the height direction, blurring of the X-ray transmission image does not occur, and high-precision detection of foreign matter is possible.

As described above, in the X-ray transmission inspection apparatus 1 of the present embodiment and the X-ray transmission inspection method using the same, the TDI in real time based on the fluctuation of the distance FOD′ measured by the distance sensor 5 when the sample S is moved. Since the TDI sensor 4 is controlled by changing the charge transfer rate of the sensor 4, the change in distance FOD' is sensed in real time, and the change is reflected in the charge transfer rate each time, thereby determining the focal position of the X-ray transmission image. It can be titrated to prevent image blur.

In addition, since it is not accompanied by a physical operation, the charge transfer speed of the TDI sensor 4 can be changed instantaneously in real time, and the time required for a series of control corresponding to the fluctuation is short, so the data acquisition interval can be shortened, more precise data acquisition becomes possible, and high-accuracy position correction of the sample S becomes possible.

Next, a second embodiment of an X-ray transmission inspection apparatus and an X-ray transmission inspection method according to the present invention will be described below with reference to FIG. 4 . In addition, in the description of the following embodiment, the same code|symbol is attached|subjected to the same component demonstrated in the said embodiment, and the description is abbreviate|omitted.

The difference between the second embodiment and the first embodiment is that, in the first embodiment, as shown in FIG. 3 , the spot shape of the laser beam L of the distance sensor 5 is a dot shape, and a line on the moving sample S In contrast to the one-dimensional measurement by , is a point where two-dimensional measurement is performed by area on the moving sample S.

That is, in the second embodiment, the distance sensor 25 irradiates the laser beam L in a linear spot shape extending in the direction intersecting the moving direction of the sample S and in the width direction of the sample S.

For example, let the spot shape of the laser beam L of the distance sensor 25 be a line shape of several tens of mm to several tens of micrometers, and let the distance from the distance sensor 25 to the measurement position be several mm - several tens of mm. All you need to do is measure, and set the optimal arrangement according to the situation.

Accordingly, in the X-ray transmission inspection apparatus and the X-ray transmission inspection method of the second embodiment, the distance sensor 25 extends in the direction in which the laser beam L intersects the moving direction of the sample S and in the width direction of the sample S. Since it is irradiated in the form of a spot on the image, it is measured in two dimensions, so that positional fluctuations in a wide area can be grasped, and further improvement in precision can be achieved.

In addition, the technical scope of this invention is not limited to each said embodiment, In the range which does not deviate from the meaning of this invention, it is possible to add various changes.

For example, the linear scale 9 for quantifying the movement amount of the sample S may be a rotary encoder, and the effect is the same as that of the linear scale.

In addition, in the above embodiment, although the enlargement ratio N calculated by the divider 6a based on the movement amount of the sample S obtained by the linear scale 9 was used, the sample movement mechanism which is the driving source serving as the basis for the movement amount of the sample S Based on the drive signal instructing (3) (motor, etc., not shown), the magnification ratio N can also be calculated.

Moreover, as the distance sensor 25 of 2nd Embodiment, it is also possible to use an area sensor. As the area sensor, in addition to having a spot shape spread two-dimensionally, a plurality of sensors having a linear spot shape may be arranged in a row. By using such an area sensor, it is possible to obtain a result of a more accurate distance measurement.

1: X-ray transmission inspection device 2: X-ray source
3: Sample transfer mechanism 4: TDI sensor
5, 25: distance sensor 6: TDI control unit
S: sample X: X-ray

Claims (4)

An X-ray source for irradiating X-rays to the sample;
a sample moving mechanism for continuously moving the sample in a specific direction while irradiating X-rays from the X-ray source;
a TDI sensor installed on the opposite side to the X-ray source with respect to the sample and detecting the X-ray that has passed through the sample;
a distance sensor for measuring the distance between the X-ray source and the sample;
X-ray penetration inspection apparatus, characterized in that it comprises a TDI control unit for controlling the TDI sensor by changing the charge transfer speed of the TDI sensor in real time based on the change in the distance measured by the distance sensor. The method according to claim 1,
The sample is in the shape of a band,
The distance sensor is a laser distance sensor that measures the distance by reflection of laser light emitted toward the sample, and a linear spot extending in a direction crossing the laser beam with a moving direction of the sample and extending in the width direction of the sample An X-ray transmission inspection apparatus characterized in that it is irradiated with a shape. An X-ray irradiation step of irradiating X-rays to the sample by an X-ray source;
a sample moving step of continuously moving the sample in a specific direction while irradiating X-rays from the X-ray source;
An X-ray detection step of detecting the X-ray passing through the sample with a TDI sensor installed on the opposite side to the X-ray source for the sample;
a distance measuring step of measuring the distance between the X-ray source and the sample with a distance sensor;
X-ray transmission inspection method, characterized in that it has a TDI control step of controlling the TDI sensor by changing the charge transfer speed of the TDI sensor in real time based on the change in the distance measured by the distance sensor. 4. The method according to claim 3,
The sample is in the shape of a band,
The distance sensor is a laser distance sensor that measures the distance by reflection of laser light emitted toward the sample, and a linear spot extending in a direction crossing the laser beam with a moving direction of the sample and extending in the width direction of the sample An X-ray transmission inspection method, characterized in that it is irradiated with a shape.

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